Artifical general intelligence system and method for medicine

ABSTRACT

A medical general intelligence computer system and computer-implemented methods analyze morpho-physiological numbers for determining a risk of an emergent disease state, determining an emergent disease state, predicting a pre-emergent disease state, determining a pre-emergent disease state, and/or predicting a risk of a pre-emergent disease state.

PRIORITY INFORMATION

This application claims the benefit of priority of U.S. Provisional Patent Application No. 61/651797 filed May 25, 2012 and titled “MEDICAL ARTIFICIAL GENERAL INTELLIGENCE: MEDICAL REASONING SYSTEM (MRS),” which is herein incorporated by reference in its entirety.

FIELD

This disclosure generally relates to an artificial intelligence system applied to the medical arts and a computerized method for making a medical diagnosis.

BACKGROUND

Biological systems are complex. Complex means that the data is nonlinear and/or dynamic. Generally, determining a risk of an emergence of a disease state (i.e., emergent disease state; a phenotype of a disease state being expressed) is an unsolvable problem in polynomial time, exponential time, or finite time. Further, generally, predicting a pre-emergence of a disease state (i.e., pre-emergent disease state; prior to actual emergence of that disease state) is an unsolvable problem in polynomial time, exponential time, or finite time.

SUMMARY

An embodiment of a computer-implemented method for determining a disease state comprises a processor accessing from a computer-readable memory, computer-readable data representing a general graph having nodes of physiological conditions, wherein each of the physiological conditions is represented by each of the nodes, wherein each of the nodes is connected by one or more edges representing correlations between the nodes, the processor accessing from the computer-readable memory, computer-readable data of physiological conditions of a patient, the processor executing computer-readable instructions for quantification of the physiological conditions of the patient, the processor transforming the physiological conditions of the patient to node data by performing quantification of the physiological conditions of the patient, the processor executing computer-readable instructions for associating the node data to the general graph, the processor creating an individualized graph by associating the node data to the general graph, the processor storing the individualized graph to the computer-readable memory, the processor accessing from the computer-readable memory, computer-readable data representing a topological module of nodes connected by edges, wherein the topological module represents the disease state, and the processor executing computer-readable instructions for mapping the topological module to the individualized graph.

An embodiment of the computer-implemented method further comprises the processor mapping the topological module to the individualized graph, wherein the disease state is an emergent disease state.

An embodiment of the computer-implemented method further comprises the processor mapping the topological module to the individualized graph, wherein the disease state is a pre-emergent disease state.

An embodiment of a computer-implemented method for creating a graph for determining a disease state comprises storing on a computer-readable memory, computer-readable data representing a general graph of physiological conditions, wherein each of the physiological conditions is represented as a node of the general graph, wherein each node is connected by one or more edges representing correlations between the nodes, and storing on the computer-readable memory, computer-readable data representing a topological module of nodes connected by edges, wherein the topological module represents the disease state, and the topological module can be mapped on to a portion of the general graph.

An embodiment of a computer-implemented method for determining a pre-emergent disease state comprises a processor accessing from a computer-readable memory, computer-readable data representing physiological conditions represented as nodes, wherein at least one of the nodes has a correlation to another one of the nodes, the processor accessing from the computer-readable memory, computer-readable data of first physiological conditions of a patient collected at a first time period, the processor transforming the first physiological conditions of the patient to first node data by performing quantification of the first physiological conditions of the patient, the processor accessing from the computer-readable memory, computer-readable data of second physiological conditions of the patient collected at a second time period, the processor transforming the second physiological conditions of the patient to second node data by performing quantification of the second physiological conditions of the patient, the processor accessing from the computer-readable memory, computer-readable data representing a topological module of nodes, wherein the topological module represents the pre-emergent disease state, the processor mapping the topological module to the first node data, the processor mapping the topological module to the second node data, and the processor determining an pre-emergent disease state based on the mapping the topological module to the first node data and to the second node data.

An embodiment of a medical general intelligence computer comprises a processor, and a computer-readable memory in communication with the processor, the computer-readable memory including and/or stored thereon one or more processor-executable instructions for the processor to perform one or more of the computer-implemented methods disclosed herein.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the drawings in which like reference numbers represent corresponding parts throughout.

FIG. 1 illustrates a box diagram of an embodiment of the MRS.

FIG. 2 illustrates an example of a graph which is a visual representation of data stored on a memory of a MRS.

FIG. 3 illustrates an example of a complex relationship view of a graph between physiological features (e.g., nodes) and their connections (e.g., edges).

FIG. 4 illustrates an example of a visual representation of an analysis process carried out by the MRS.

FIG. 5 illustrates examples of topological modules.

FIGS. 6-8 illustrate an embodiment of the AGI method.

FIG. 9 illustrates an example of the numerical analysis of node values which can be performed by the MRS.

FIG. 10 illustrates an example of the steps carried out by the MRS using the AGI method.

FIG. 11 illustrates an example of an emergent disease state vs. non-emergent disease state.

FIG. 12 illustrates an example of an individual's physiological data collected along a time dimension.

FIG. 13 shows an example chart showing a change in the disease intensity along a time dimension.

FIG. 14 illustrates an example of a chart resulting from the MRS performing a metadata analysis of temporal data.

DETAILED DESCRIPTION

The embodiments disclosed are directed towards a computerized general intelligence systems applicable to the medical arts and a computerized method for determining risks associated with a medical diagnosis.

Generally, without a reproducible numerical descriptor, a particular disease state is difficult to define, predict, and/or manage. Generally, useable medical data for defining, predicting, and/or managing a disease are numerical values associated with morpho-physiologic features. Such numerical values are defined herein as morpho-physiological numbers. Examples of morpho-physiological features are, for example but not limited to, weight, heart rate, blood pressure, etc. Examples of morpho-physiological numbers are, for example but not limited to, 200 lbs (weight), 50 beats per minute (heart rate), 160 mmHg (systole)/120 mmHg (diastole) (blood pressure), etc.

The morpho-physiological numbers are different from data rising out of a person's genetic makeup. That is, a person's genetic makeup (DNA) is generally a fixed micro-level blueprint which represents a genetic potential of the person. The person's genetic makeup does not represent the person's current physiological state at a macro-level and real world conditions. That is, it is impossible to determine whether the person is currently suffering from a disease state by looking only at the genetic makeup of that person. The morpho-physiological features and numbers of the person must be determined and analyzed to determine whether the person is currently suffering from a disease state (i.e, clinical descriptor).

Clinical descriptors such as “congestive heart failure”, “cancer”, etc. provide a name, or an identity, to a disease state. For example, a person with a blood pressure numbers (morpho-physiological numbers) of 160 mmHg (systole)/120 mmHg (diastole) can be determined to have Arterial Hypertension, i.e., high blood pressure (clinical descriptor). However, a disease state of a biological system (e.g., animal, human, etc.) is rarely a consequence of an abnormality in a single physiological feature. Instead, the disease state reflects perturbations of a complex physiological network of linked morpho-physiological features (e.g., tissues, organs, etc.). Thus, while the clinical descriptors are a convenient way of communicating in few words the complex perturbations of the physiological network, the clinical descriptors, by themselves, have not been able to provide sufficient information for numerical and/or computational analysis needed for determining risk levels and/or management levels of perturbations of many morpho-physiological features. That is, the clinical descriptors have been considered useless for numerical evaluations because the clinical descriptors are not numbers. For example, the clinical descriptor of “cancer” (of a patient who is suffering from cancer) has not itself been directly used for numerical and/or computational evaluation of the patient's current state of suffering from the disease, nor for determining risks of other related physiological conditions and/or disease states that the patient may suffer from in the near or distant future. That is to say, clinical descriptors (e.g., names of diseases) were conceived for the sake of easily communicating complex physiological phenomenon between humans. Clinical descriptors have not been directly computable. Accordingly, clinical descriptors had not been used in determining and/or predicting risk levels of these perturbations of the morpho-physiological features. Additionally, clinical descriptors had not been used in determining and/or predicting an emergent disease state and/or a pre-emergent disease state.

Disclosed herein are systems and methods that define clinical descriptors as a connection of morpho-physiological features, such that the clinical descriptors can be used in determining and/or predicting risk levels of these perturbations of the morpho-physiological features.

Disclosed herein are systems and methods that define clinical descriptors as a connection of morpho-physiological features, such that the clinical descriptors can be used in determining and/or predicting an emergent disease state and/or a pre-emergent disease state.

The systems and methods disclosed herein define clinical descriptors as quantifiable information. The systems and methods disclosed herein can describe clinical descriptors as multi-dimensional computer-readable data representing a topology of quantifiable morpho-physiological features.

The topology is described herein as a topological module. The morpho-physiological features are described herein as nodes and/or hubs. The morpho-physiological numbers are described herein as numerical values for the associated morpho-physiological features (nodes and/or hubs). Accordingly, the topological module is a network representation of connected nodes and/or hubs. Thus, clinical descriptors of diseases are represented as computer-readable data represented as a network connections and/or relationships of numbers associated with nodes and hubs. Accordingly, clinical descriptors, and a disease state, can also be visually represented as a graph having a network of connected nodes, wherein at least a portion of the graph can have a topological module of nodes connected by edges, wherein the topological module represents the disease state. Therefore, according to the embodiments herein, clinical descriptors can be numerically analyzed and computed.

A Medical Reasoning System (MRS) is a specialized medical general intelligence computer configured to perform the computer-implemented methods disclosed herein. The MRS comprises a processor, and a computer-readable memory in communication with the processor. The computer-readable memory stores thereon one or more processor-executable instructions for the processor to perform one or more of the computer-implemented methods disclosed herein.

FIG. 1 illustrates a box diagram of an embodiment of the MRS 100. The MRS 100 is a specialized medical general intelligence computer configured to perform one or more of the computer-implemented methods disclosed above. The MRS 100 comprises a processor 102, and a computer-readable memory 104 in communication with the processor 102. The computer-readable memory 104 stores thereon one or more processor-executable instructions for the processor 102 to perform one or more of the computer-implemented methods disclosed above. The computer-readable memory 104 can store one or more of computer-readable data, graph data, node data, node value, hub data, hub value, edge data, topological module data, individualized graph data, meta-data, and inference data. Examples of the computer-readable memory 104 are non-transitory storage medium, such as but are not limited to, magnetic media (disc, film, ribbon, etc.), optical media (disc, film, ribbon, etc.), ROM, RAM, flash media, solid state drive, etc. The MRS 100 is configured with one or more Input/Output (I/O) device(s) 106 which is in communication with the processor 102. Examples of the I/O device(s) 106 include but are not limited to a keyboard, a mouse, a touchscreen, a display device, etc. The I/O device(s) 106, such as the touchscreen and/or the display device, can display thereon a graphical user interface (GUI) for a user to interact with the MRS 100. The GUI provides for displaying of information to the user and can receive user input via the user's interaction with the GUI.

The I/O device(s) 106 are device(s) configured to allow a user to interact with the MRS 100 and/or for the MRS 100 to interact with the user. Accordingly, one or more I/O device(s) 106 can provide for entering data (input), displaying data (output), displaying results of the analysis (output), etc.

An embodiment of the MRS 100 is configured to operate a computerized-method including an Artificial General Intelligence (AGI) method. The MRS 100 can analyze a topological module and morpho-physiological numbers for determining and/or predicting risk levels of perturbations of the morpho-physiological features. Further, the MRS 100 can analyze a topological module and morpho-physiological numbers for determining a risk of an emergent disease state. Further, the MRS 100 can analyze a topological module and morpho-physiological numbers for determining an emergent disease state. The MRS 100 can analyze a topological module and morpho-physiological numbers for predicting a pre-emergent disease state. Further, the MRS 100 can analyze a topological module and morpho-physiological numbers for determining a pre-emergent disease state. Further, the MRS 100 can analyze a topological module and morpho-physiological numbers for predicting a risk of a pre-emergent disease state.

An embodiment of the methods performed by the MRS 100 includes a medical application of an “artificial general intelligence (AGI)” method. The AGI method described herein are directed to simplifying complex events. The AGI method can be applied to many different domains. Thus, the AGI method is domain-independent. The AGI method does not attempt to replicate and/or compute every feature of a complex event. In contrast, the AGI method takes the features of the complex event, and simplifies the complex event to few features that are determined to be essential and/or important to that complex event. Accordingly, the AGI method allows for extremely fast computation and/or analysis of complex events.

The computer-implemented method including the AGI can integrate an “autonomous learning,” which is described herein to mean that the computer system can perform analysis of data without supervision by a person. The computer-implemented method including the AGI can integrate a “goal-directed learning,” which is described herein to mean that the computer system can perform selective analysis of data towards a goal set by the computer, without supervision by a person. The computer-implemented method including the AGI can integrate an “adaptive learning,” which is described herein to mean that the computer system can perform cumulative and contextual analysis of data without supervision by a person. Adaptive learning can lead to additional data (e.g., new data).

The computer-implemented method including the AGI can include pattern recognition and pattern matching (e.g., mapping). Accordingly, the computer-implemented method including the AGI can include determining an inference between one set of data (wherein “set” can be one or more value(s)) to another set of data. An example of the inference between sets of data includes sets of data for same parameters taken at different times. The AGI method understand the concept of the time-dimension for these sets of data, and based on the changes in the sets of data, an inference data can be created as meta-data for the collective sets of the data.

The MRS 100 configured to perform the medical application of the AGI method can perform an analysis of data without the need to use disease-dependent language. That is, the MRS 100 can use data having disease-independent language. The data used by the MRS 100 are formulated and associated in the terms and statements derived from experience-grounded semantics. That is, the formulations and the associations of the terms are pre-determined and determined based on experiences arising out of research (which a user inputs into and stored in the system memory) and/or self-learning (e.g., autonomous, goal-directed, and/or adaptive). An example of self-learning data includes but is not limited to inference rules of nodes determined by the system based on the data stored in the memory.

The embodiments disclosed herein are also directed to the MRS 100 and methods for performing an analysis (e.g., mapping) of one or more topological modules stored in the memory in comparison to the morpho-physiological numbers of nodes and/or hubs, determining a pre-emergent disease state (and/or risk(s) thereof). The embodiments can also provide an output for suggested management of particular morpho-physiological feature(s) for preventing an emergence of the pre-emergent disease state.

FIG. 2 illustrates an example of a graph 200 which is a visual representation of data stored on a memory of a MRS. The graph 200 is formed of a plurality of nodes 202, 204, 206 connected via edges 208, 210, 212, 214, 216, 218. Each edge 208, 210, 212, 214, 216, 218 connects two nodes. For example, edge 208 connects nodes 202 and 204. A node 202 can have one edge 208 connected thereto. A node 206 can have multiple edges 210, 212, 214, 216, 218 connected thereto. A node 206 having more than a set number of edges connected thereto can be determined to be a hub. For example, if the set number is 3, then the node 206 is a hub 206. Each node 202, 204 and hub 206 of the graph 200 can have a numerical value associated with it. The graph 200 may be a general graph, which does not have numerical values (or the numerical values are null values) associated with each of the nodes 202, 204 and hub 206.

The MRS includes a processor that can access the memory for building the graph 200, modifying the graph 200 by adding additional nodes, hubs, and/or edges, removing nodes, hubs, and/or edges, etc. Such modifications can be done by a user interacting with the MRS and/or self-learning by the MRS by appropriate analysis of other data. For example, if a new research shows that an association between node 202 and node 204 does not exist, then the processor of the MRS can access the memory and remove the edge 208 associating the nodes 202, 204. This can be performed by the user purposefully interfacing with the MRS to remove the data representing the edge 208 of the graph 200, or the user can enter the change in the relational information between the two features that are represented as nodes 202, 204 and edge 208, and the processor of the MRS automatically, and dynamically, changes the data representing the graph 200 accordingly (by removing the edge 208). Addition(s) of one or more of the nodes, hubs, and edges can also be performed by the user purposefully interfacing with the MRS, or the processor of the MRS automatically, and dynamically, changing the data representing the graph 200 according to new information the MRS has access to.

Each of the nodes 202, 204, 206 represents a computer-readable data of a physiological feature (e.g., condition of a person, animal, etc.). Each of the edges 208, 210, 212, 214, 216, 218 represents a relationship (e.g., association, causation, inference, etc.) between two physiological features. For example, in the medical domain of cardiology, early diastolic velocity of the mitral valve annulus (e′) and a ratio E/e′ (wherein E is an early transmitral flow velocity) are related features. Thus, the node representing e′ and the node representing E/e′ would have an edge connecting them together. Also, the node representing E and the node representing E/e′ would have an edge connecting them together. Further, because E/e′ feature is related to left ventricular diastolic pressure (LVDP), a node representing E/e′ would have an edge connecting to a node representing LVDP.

The processor can create a set of data representative of an individualized graph for a particular individual by populating the nodes of the graph 200 with numerical values representing the quantified (e.g., measured) physiological condition of the individual. The numerical values may be a scaled value (e.g., 1 to 4), wherein the scaled value is a translation of real measured value. The processor can store the individualized graph to the memory of the MRS. For example, when the processor receives an individual's physiological data for e′ and E, the processor can populate the respective nodes for e′, E, and E/e′ with the physiological data and/or scaled values representing the received physiological data based on a set ranges (stored in the memory) for the respective physiological features. Accordingly, the processor can create the individualized graph for the particular individual by populating the nodes e′, E, and E/e′ with quantifiable numerical values. The processor may determine not to populate one or more of nodes of the graph 200 with one or more of the received physiological data when creating the individualized graph. Such determination can be made by the processor when the physiological data includes information for a node that represents a less important feature (e.g., has only one edge connected to another node (which is not a hub)).

FIG. 3 illustrates an example of a complex relationship 300 view of a graph (e.g., graph 200 shown in FIG. 1) between physiological features (e.g., nodes) and their connections (e.g., edges). The curve 302 represents a power law relationship between the physiological features 304 and their interconnectivities (i.e., connectivity) 306. The Y-axis 308 represents the number of quantifiable physiological features 304. The X-axis 310 represents the number of connectivity 306 that exist between the features. According to the power law curve 302, there are very few quantifiable physiological features 304 what have high connectivity 306. Dimensionally compressed view 312 of the curve 302 shows that there are many features (nodes) 314 with few connections, and that there are a small number of features (hubs) 316 with high number of connections.

FIG. 4 illustrates a visual representation 400 of an analysis process (e.g., mapping) carried out by the processor of the MRS, wherein a clinical descriptor has been transformed into a topological module 402.

The MRS can represent one or more clinical descriptors (diseases) as quantifiable association of physiological features and quantifiable data. That is, the MRS can represent clinical descriptors of diseases are represented as computer-readable data represented as a network connections and/or relationships of numbers associated with nodes and hubs. Accordingly, clinical descriptors, and a disease state, can also be visually represented as a topological module 402 having a network of connected nodes.

The topological module 402 has been mapped onto a graph 404 in the visual representation 400. The mapping can be performed by pattern recognition and/or pattern matching method performed by the processor of the MRS. For the visual representation 400, the topological module 402 is indicated by a border (e.g., surface created by a network of nodes and edges representing the topological module 402). The topological module 402 represents a group of nodes wherein their perturbations are validated to be linked to a particular disease. The topological module 402 has nodes (features) that are considered to be necessary to specific disease states. The MRS employing the AGI method can segregate non-essential nodes and removes them from being consideration (computational analysis does not include non-essential nodes). For example, the topological module 402 includes a network of nodes that are less connected 406 (shown as open circles). The topological module 402 includes nodes that are highly connected 408 (shown as closed circles). The MRS employing the AGI method can segregate the less connected nodes 406 (shown as open circles) as non-essential nodes of the topological module 402 and need not consider them for further analysis of making a medical determination and/or prediction associated with the topological module 402 and an individual's physiological data. Only the highly connected nodes 408 (A, B, C, D, E) of the topological module 402 can be considered. The term highly connected means that the number of edges connected to a node is greater than a set number. In this example, the set number is four. Each of the highly connected nodes 408 (A, B, C, D, E) have number of edges connected thereto that is greater than four. The set number can be changed as needed and/or desired by the MRS and/or a user.

The processor of the MRS can create a disease module 410 into memory, represented by the highly connected nodes 408 (A, B, C, D, E). However, the MRS need not create a separate module 410 from the topological module 402. Further analysis can be performed using the topological module 402, but considering only the highly connected nodes 408 (ignoring the less connected nodes 406), instead of creating a separate disease module 410 into memory. Accordingly, the terms topological module and disease module can be used interchangeably, wherein the term disease module defines a subset of highly connected nodes of the topological module of a disease state. Accordingly, the disease module 410 can be viewed as a breakdown of the topological module 402.

Further, the highly connected nodes 408 can be defined to be a macro node. The macro node is used herein to mean a network of the fewest number of the most highly connected disease associated nodes. Accordingly, the macro node can represent a single quantifiable measure of a feature-to-disease expression. For each clinical descriptor, a macro node can be determined by the above process. The macro nodes can be stored into the memory of the MRS. The macro nodes can be used in an inference process to compute the dynamical integrity (coherence, intensity, variance, etc.) of a particular emergent disease.

FIG. 5 illustrates examples of topological modules 502, 504 which can be mapped onto the graph 500. Each of the topological modules 502, 504 represents a disease state (i.e., clinical descriptor). The MRS can map one or more of the topological modules 502, 504 onto the graph 506. The MRS can determine that at least a portion of the graph 506 represents one or more topological modules 508, 510 by, for example, pattern matching and/or pattern recognition. Accordingly, the topological module 502 has the same network structure as the topological module 508 mapped onto graph 506, and the topological module 504 has the same network structure as the topological module 510 mapped onto graph 506. Whereas, the topological modules 502, 504 viewed separately does not necessary convey any information about their association, when mapped onto the graph 506 as topological graphs 508, 510, it can be determined that the topological graphs 508, 510 have overlapping nodes (A, B) 512, 514. Further, the topological modules 502, 504 viewed separately may not necessarily convey the information that the nodes (A, B) 512, 514 are both highly connected nodes, because each of the nodes 512, 514 in the topological modules 502, 504 have only three edges connected thereto. However, when mapped onto the graph 506 as topological graphs 508, 510, it can be determined that the overlapping nodes (A, B) 512, 514 are both highly connected nodes (i.e., hubs) for both topological modules 508, 510. Accordingly, by the mapping process, the MRS can determine that there is an inference relationship, represented by the overlapping nodes (A, B) 512, 514, between the two disease states represented by the topological modules 502, 504.

FIGS. 6-8 illustrate an embodiment of the AGI method for simplifying a complex network of physiological features to few highly connected hubs for making an inference between two sets of topological modules.

FIG. 6 illustrates a visual representation 600 of a topological module 602 of a disease state (e.g., emergent disease) mapped onto a graph 604.

FIG. 7 illustrates a visual representation 700 of the topological module 602, wherein overlapping nodes 702, 704, 706, 708 (closed circles) of the topological module 602 and another topological module (402 shown in FIG. 4).

FIG. 8 illustrates a visual representation 800 of a portion of the graph (604 shown in FIGS. 6 and 7) showing only the inference nodes 702, 704, 706, 708. These inference nodes 702, 704, 706, 708 can be defined to be a macro node 802 for the two topological modules (402 shown in FIGS. 4 and 602 shown in FIG. 6). That is, the macro node 802 is a network of the fewest number of the most highly connected disease associated nodes 702, 704, 706, 708 for both topological modules (402 shown in FIGS. 4 and 602 shown in FIG. 6). Accordingly, the AGI method carried out by the MRS can determine that the same macro node 802 exists for the disease states represented as topological modules (402 shown in FIGS. 4 and 602 shown in FIG. 6). This inference relationship data can be stored into the memory of the MRS. The macro node 8002 and inference relationship data can be used in an inference process to determine an emergent disease and pre-emergent disease. For example, if the topological module 402 (shown in FIG. 4) is an emergent disease, and the topological module 602 (shown in FIG. 6) is a pre-emergent disease, the inference nodes determined by the MRS allows the MRS to predict that the emergence of the disease represented by the topological module 402 (shown in FIG. 4) means that the disease represented by the topological module 602 (shown in FIG. 6) will or is highly likely to emerge. Numerical analysis of the node values can be performed by the MRS to calculate the risks of the emergence of pre-emergent disease state represented by the topological module 602 (shown in FIG. 6).

FIG. 9 illustrates an example of the numerical analysis of node values which can be performed by the MRS. The data/features contained within a disease module are typically nonlinear and vacillate among various state weights. A disease is rarely a consequence or reflection of a single data/feature but reflects the perturbations of a complex network that links multiple data/features. Disease module behavior is not random but a series of general organizing principals in their structure and evolution. Data/feature nodes are interdependent and continuously readjust in order to stabilize their integrated state.

FIG. 9 shows a chart 900 for performing a numerical analysis of values for five nodes 902, 904, 906, 908, 910. For example, the nodes 902, 904, 906, 908, 910 can be hubs of a topological module for a disease state. The topological module may be mapped onto a graph, wherein each of the nodes 902, 904, 906, 908, 910 has physiological data of an individual for creating an individualized graph.

A scaled value is assigned by the MRS for the physiological data for each of the nodes 902, 904, 906, 908, 910. That is, each node 902, 904, 906, 908, 910 represents a group of highly connected physiological features that represent a disease state, and physiological data has been received by the MRS. The MRS scales the physiological data for each of the physiological features (nodes 902, 904, 906, 908, 910) and assigns the scaled value to the nodes 902, 904, 906, 908, 910. The scaled values can be, for example but not limited to, integer values from 0 to 3, wherein 0=normal, 1=mild, 2=moderate, 3=severe. The scaled values represent a degree of perturbation for each of the physiological feature (node 902, 904, 906, 908, 910).

The chart 900 shows that the physiological data of the individual for the physiological feature (node 902) is severely perturbed from normal (scaled value=3).

The chart 900 shows that the physiological data of the individual for the physiological feature (node 904) is moderately perturbed from normal (scaled value=2). The chart 900 shows that the physiological data of the individual for the physiological feature (node 906) is mildly perturbed from normal (scaled value=1).

The chart 900 shows that the physiological data of the individual for the physiological feature (node 908) is mildly perturbed from normal (scaled value=1).

The chart 900 shows that the physiological data of the individual for the physiological feature (node 910) is severely perturbed from normal (scaled value=3).

The MRS can calculate a Total module weight 912 from the scaled values of the five nodes 902, 904, 906, 908, 910. For example, the Total module weight 912 can be a sum of the scaled values of the five nodes 902, 904, 906, 908, 910, which is 10. A maximum modular weight value can be determined based on the number of nodes in the topological module and the maximum scale value (in this example, 3) for each node. The maximum modular weight is a value represented by the maximum scale value (in this example, 3) multiplied by the number of nodes (in this example, 5). Thus, in this example, the maximum modular weight is 3×5=15.

The MRS can calculate a Variance 914 of the individual's physiological data from normal by, for example, dividing the Total module weight 912 (value of 10) by a maximum modular weight (value of 15). This ratio is the Variance 914. Accordingly, the Variance 914 can be a real number scaled from 0.0 to 1.0, wherein 0.0 represents absolute normalcy, and 1.0 represents severe variance from normal. Another form of numerical scale may be used. In this example, the Variance 914 is 10/15=0.67. That is, the physiological state of this individual has a Variance 914 from normal of 0.67. Accordingly, a single numerical value can be used in quantifying numerically and computationally determining perturbations and variance of an individual's physiological state from normal with respect to a clinical descriptor (disease state). In this example, the Variance 914 of 0.67 would indicate a “moderate” clinical state 916 in relation to the disease state represented by the nodes 902, 904, 906, 908, 910. An inference state 918 is a value determined by the maximum scaled value multiplied by the weight average value. The inference state 918 is related to a probability of an event given the occurrence of another event. That is, the inference state 918 value can be used in determining a quantifiable risk of emergence of another disease state. In this example, the maximum scaled value is 3, and the weight average value is 0.67. Thus, the inference state 916 value is 3×0.67=2.1. The steps in the process shown in FIG. 9 and described in relation to FIG. 9 are performed by the MRS.

FIG. 10 illustrates another example of the steps carried out by the MRS using the AGI method.

In Step 1, the MRS performs a node aggregation step to a network of nodes, reducing the total network (e.g., graph) using node aggregation into a small singly connected graph 1000. The MRS identifies a macro node, or a set of fewest highly connected nodes 1002, 1004, 1006 (i.e., hubs) in the graph 1000. The MRS can computationally represent these hubs 1002, 1004, 1006 as an aggregated set of features (A, B, C) 1008 forming the macro node 1010.

In Step 2, the MRS transforms the graph 1000 into a scaled value (i.e. numerical state) 1012 for each hub 1002, 1004, 1006, wherein each of the scaled value represents a clinically equivalent range for the physiological feature represented by the hub 1002, 1004, 1006. For example, the scaled values can represent qualitative states 1014 of normal, mild, moderate, and severe.

In the example shown, the physiological features represented by nodes A 1002 and C 1006 are determined by the MRS to be “moderate” and to have the scaled values of 2. The physiological feature represented by node B 1004 is determined by the MRS to be “severe” and to have the scaled value of 3.

In Step 3, the MRS determines that the number of hubs 1002, 1004, 1006 defining the disease state (topological module) is 3 1016, the summed group state is 7 (i.e., 2+2+3) 1018, the maximum state of the disease state is 9 (i.e., physiological condition of an emergent disease state) 1020, and the current condition value in relation to the disease state is 0.78 (i.e., summed group state divided by the maximum state=7/9=0.78) 1022. This current condition value infers the magnitude of variance from normal in relation to the disease state represented by the topological module defined by the hubs 1002, 1004, 1006.

Following are examples of hubs of a macro node which defines a disease state, and clinical ranges of the physiological data for the qualitative states of normal, mild, moderate, and severe. The qualitative states of normal, mild, moderate, and severe can be assigned scaled values of 0, 1, 2, and 3, respectively. The following examples and many other topological modules can be stored in the memory of the MRS. The MRS can receive patient data having physiological data for the following features, apply the AGI method described herein, and determine and/or predict the related emergent disease state and/or pre-emergent disease state. The MRS can receive patient data having physiological data for the following features, apply the AGI method described herein, and determine a risks for the related pre-emergent disease states from becoming emergent.

EXAMPLE 1 Endocrinology Disease State: Diabetes

Hub Normal Mild Moderate Severe Hgb A1c % <5.7 to 6.4 ≧6.4 to 7.5    >7.5 to 8.5    >8.5 GFR ≧70 70 to 50 50 to 30 <30 Glomerular filtration rate mL/min/ 1.73 m² Hemoglobin 13.8 to 17.2 M <12 12 to 10 <10 gm/dL 12.1 to 15.1 F Weight (BMI)  <25.0 25.0 29.9   30-39.9 ≧40

EXAMPLE 2 Gastroenterology Disease State: Celiac Disease

Hub Normal Mild Moderate Severe TTG antibody Negative Variable Positive Test (anti- 10X abnormal transglutaminase antibodies) EMA-IgA Negative Variable Positive Anti-endomysial antibody HLA Genetic Negative Variable Positive Tissue Type (30% over (human diagnosis) leukocyte antigen Small Bowel Negatve Sampling Error Positive Biopsy Variable

EXAMPLE 3 Hepatology Disease State: Light Chain Amyloidosis

Hub NORMAL or ABSENT PRESENT Serum-Immune Fixation Yes/No Yes/No Urine-Immune Fixation Yes/No Yes/No Free Immunoglobulin Light Chain >⅓ ratio >3 ratio Kappa/Lambda ratio

EXAMPLE 4 Oncology Disease State: Pancreatic Cancer

Hub Normal Mild Moderate Severe CA 19-9 37-50 >100 (carbohydrate antigen 19-9) Cancer antigen 19-9 Chronic None Mile Chronic Severe Epigastric Pain intermittent Jaundice None Document Screening CT Image of an None Positive Positive epigastric mass (Possible) (Definite)

EXAMPLE 5 Pulmonology Disease State: Obstructive Airway

Hub Normal Mild Moderate Severe FEV1/FVC ratio <70% >70% Total Lung Capacity >80% 60-80 50-50 <50% Residual Volume ≦100 150 (RV/TLC ratio) DLC >80% <30% Diffusing Lung Capacity

EXAMPLE 6 Rheumatology Disease State: Rheumatoid Arthritis

Hub Normal Low Moderate High Tender Joints 0 28 Swollen Joints 0 28 Sedimentation 0-15 0-20 men Rate (mm/hr) 0-20 0-30 fem C-Reactive <1.0 <3.0 Protein-hs mg/L Pain Scale (%) 0 100 Global Patient 0 100 Scale (%) Global 0 100 Physician Scale (%)

FIG. 11 illustrates how the MRS determines and differentiates between an emergent disease state vs. non-emergent (or pre-emergent) disease state. In Status A 1100 and Status B 1102, the hubs (e′=myocardial relaxation; E/e′=filling pressure; LAVI=chronicity of filling pressure; E/A and DT=acuity of filling pressure) for heart failure state are provided. The MRS reads the hubs 1104 from the memory of the MRS and processes physiological data received by the MRS, and determines the quantitative and qualitative state for each of the hubs 1104. In State A 1100, the qualitative states for the hubs 1104 are e′=moderate, E/e′=mild, LAVI=moderate, E/A=moderate, and DT=moderate. The MRS can perform the AGI method of quantitative determination of variance and conclude that the received physiological data in Status A 1100 is asymptomatic. That is, Status A 1100 is determined to have non-emergent disease for hear failure.

In contrast, for Status B 1102, the MRS reads the hubs 1104 from the memory of the MRS and processes a different (either of another individual from Status A, or from the same individual as Status A but at a different time) physiological data received by the MRS, and determines the quantitative and qualitative state for each of the hubs 1104. In State B 1102, the qualitative states for the hubs 1104 are e′=moderate, E/e′=severe, LAVI=severe, E/A=severe, and DT=severe. The MRS can perform the AGI method of quantitative determination of variance and conclude that the received physiological data in Status B 1102 has an emergent disease, i.e., heart failure.

FIG. 12 illustrates an example of an individual's physiological data 1200 collected along a time dimension (e.g., data has been collected many times at different times). The hubs 1202 (Left atrial volume index LAVI, Tissue Doppler myocardial relaxation e′, Left ventricular filling pressure E/e′, Mitrial valve deceleration time DT, Mitral valve MV) define the disease state of Atrial Fibrillation. At one point in time, the MRS has determined, based on the analysis of the values for the hubs 1202, that the individual does not have an emergent Atrial Fibrillation disease state. For example, the qualitative states of the hubs 1202 for time 1204 are all normal.

Yet, at another point in time 1206, the MRS has determined, based on the analysis of the values for the hubs 1202, that the individual does have an emergent Atrial Fibrillation disease state. For example, the qualitative states of the hubs 1202 for time 1206 are LAVI is abnormally large, e′ is abnormally low, E/e′ is highly variable, MV and DT are both abnormally variable. The MRS can determine during the time period 1208 that the individual is heading towards the emergent condition shown at time 1206. Periodic measurements of the physiological data for the hubs 1202 during the time 1206 received by the MRS can be used in determining the total variance value (or disease intensity). As described above (for example, FIG. 9), the disease intensity is a single numerical value (per taking of a physiological data) which can be used in quantifying numerically and computationally determining perturbations and variance of an individual's physiological state from normal with respect to a disease state. This disease intensity value can be measured at different times, and the MRS can determine a trend in the change of the disease intensity value.

For example, FIG. 13 shows a chart 1300 showing a change in the disease intensity 1302 (Y-axis) along a time dimension 1304 (X-axis). The MRS can determine the intensity state 1302 of two disease modules (i.e., chronicity 1306 and acuity 1308) over the time dimension 1304. The MRS calculates and stores disease intensity values of the disease modules 1306, 1308. The MRS can infer a relationship between the two disease modules 1306, 1308 because the change in the data for the two disease modules along the time dimension shows an interdependence phenomena. Chronicity (historical burden of left ventricular filling pressure) and acuity (burden of filling pressure at the time of data acquisition) can be drawn as a chart 1302 along the time dimension 1304 (the MRS can computationally determine this relationship without necessarily graphing the chart 1304). The acuity 1308 evolves to a lower degree of intensity and chronicity to a higher degree of intensity. Based on these time dependent changes the MRS can provide an output via the I/O device(s) for a user so that the user can appreciate the interdependency of data and make a more informed management decision.

FIG. 14 illustrates an example of a chart 1400 resulting from the MRS performing a metadata analysis of temporal data, for the disease Heart Failure, using hubs e′, LAVI, E/e′, DT, and E/A. The MRS determines a disease intensity (or variance) from a numerical analysis using the AGI method for an individual's physiological data in relation to a disease module. The chart 1400 includes a disease intensity 1402 (Y-axis) having a value of 0 (normal) to 1 (severe). The chart 1400 has the time dimension along the X-axis. Thus, a first disease intensity 1404 is determined by the MRS for a 1st exam date. A second disease intensity 1406 is determined by the MRS for a 2nd exam date. A third disease intensity 1408 is determined by the MRS for a 3rd exam date. A fourth disease intensity 1410 is determined by the MRS for a 4th exam date. A table of the disease intensities are shown in the table below. Further, based on the differences between the disease intensities, the MRS can determine qualitative information as to whether the individual is improving or deteriorating in time.

1st exam 2nd exam 3rd exam 4th exam date date date date Disease Intensity 0.89 0.61 0.5 0.79 Change Beginning Improve Improve Deteriorate Accordingly, the MRS metadata analysis is cable of exhibiting a robust expressions of disease status and tracking of management decisions.

The MRS can predict, based on the quantified numerical analysis using the AGI method of processing hubs related to a topological module and emergent conditions, one or more events that are pre-emergent. Further, based on the predicted events, the MRS can provide an output via I/O device(s) a suggested physiological and/or medical management/treatment for preventing the emergence of the predicted event.

The table below provides some examples of the MRS making a determination of an emergent condition, predicted event(s), and suggested management output.

Hubs Emergent Predicted Suggested Management (features) = Condition = Event(s) = Output Blood Pressure + = Hypertensive = Stroke, Heart = Medical Management Cardiac Heart Disease Failure, Renal Dysfunction Failure, etc. Ejection = Systolic = Heart Failure, = Medical/Surgical Fraction + Cardiac Coronary Artery Management Systolic Dysfunction Disease myocyte excursion (fibrosis) + wall motion Myocyte = Diastolic = Stroke, = Medical Management relaxation + Cardiac Congestive elevation LV Dysfunction Heart Failure filling pressure Multivariable = Valve = Stroke, Heart = Medical/Surgical echo/Doppler Disease Failure, Death Management hemodynamic profile Myocardial = Atrial = Stroke, Heart = Medical/Surgical relaxation (e′) + Fibrillation Failure, Death Management chronicity of LV filling pressure

The MRS can proceed with autonomous learning based on the graph, topological modules, and physiological data received and stored in the memory of the MRS. For example, where the MRS performs variance determinations based on hubs of a particular topological module, the MRS can include one or more nodes (having fewer connections than the hubs) of the topological node in addition to the hubs. Further, the MRS can substitute one or more of the hubs with one or more of the nodes. If the resulting variance and other quantitative analysis values are the same or substantially similar to the values determined by using only the hubs, the MRS stores that data, so that in certain situations when a set of physiological data is received by the MRS and the received data is lacking towards a value related to one or more of the hubs, the MRS “knows” that another data value (if available) can be substituted and/or used in place of the missing hub value in making the determination and/or prediction.

With regard to the foregoing description, it is to be understood that changes may be made in detail without departing from the scope of the present invention. It is intended that the specification and depicted embodiment to be considered exemplary only, with a true scope and spirit of the invention being indicated by the broad meaning of the claims. 

What is claimed is:
 1. A computer-implemented method for determining a disease state, the method comprising: a processor accessing from a computer-readable memory, computer-readable data representing a general graph having nodes of physiological conditions, wherein each of the physiological conditions is represented by each of the nodes, wherein each of the nodes is connected by one or more edges representing correlations between the nodes; the processor accessing from the computer-readable memory, computer-readable data of physiological conditions of a patient; the processor executing computer-readable instructions for quantification of the physiological conditions of the patient; the processor transforming the physiological conditions of the patient to node data by performing quantification of the physiological conditions of the patient; the processor executing computer-readable instructions for associating the node data to the general graph; the processor creating an individualized graph by associating the node data to the general graph; the processor storing the individualized graph to the computer-readable memory; the processor accessing from the computer-readable memory, computer-readable data representing a topological module of nodes connected by edges, wherein the topological module represents the disease state; and the processor executing computer-readable instructions for mapping the topological module to the individualized graph.
 2. The computer-implemented method as in claim 1, further comprising: the processor mapping the topological module to the individualized graph, wherein the disease state is an emergent disease state.
 3. The computer-implemented method as in claim 1, further comprising: the processor mapping the topological module to the individualized graph, wherein the disease state is an pre-emergent disease state.
 4. A computer-implemented method for creating a graph for determining a disease state, the method comprising: storing on a computer-readable memory, computer-readable data representing a general graph of physiological conditions, wherein each of the physiological conditions is represented as a node of the general graph, wherein each node is connected by one or more edges representing correlations between the nodes; and storing on the computer-readable memory, computer-readable data representing a topological module of nodes connected by edges, wherein the topological module represents the disease state, and the topological module can be mapped on to a portion of the general graph.
 5. A computer-implemented method for determining a pre-emergent disease state, the method comprising: a processor accessing from a computer-readable memory, computer-readable data representing physiological conditions represented as nodes, wherein at least one of the nodes has a correlation to another one of the nodes; the processor accessing from the computer-readable memory, computer-readable data of first physiological conditions of a patient collected at a first time period; the processor transforming the first physiological conditions of the patient to first node data by performing quantification of the first physiological conditions of the patient; the processor accessing from the computer-readable memory, computer-readable data of second physiological conditions of the patient collected at a second time period; the processor transforming the second physiological conditions of the patient to second node data by performing quantification of the second physiological conditions of the patient; the processor accessing from the computer-readable memory, computer-readable data representing a topological module of nodes, wherein the topological module represents the pre-emergent disease state; the processor mapping the topological module to the first node data; the processor mapping the topological module to the second node data; and the processor determining the pre-emergent disease state based on the mapping the topological module to the first node data and to the second node data.
 6. A medical general intelligence computer, comprising: a processor; and a computer-readable memory in communication with the processor, the computer-readable memory including processor-executable instructions for determining a pre-emergent disease state, wherein when the processor executes the processor-executable instructions, the processor accesses from the computer-readable memory, computer-readable data representing physiological conditions represented as nodes, wherein at least one of the nodes has a correlation to another one of the nodes; the processor accesses from the computer-readable memory, computer-readable data of first physiological conditions of a patient collected at a first time period; the processor transforms the first physiological conditions of the patient to first node data by performing quantification of the first physiological conditions of the patient; the processor accesses from the computer-readable memory, computer-readable data of second physiological conditions of the patient collected at a second time period; the processor transforms the second physiological conditions of the patient to second node data by performing quantification of the second physiological conditions of the patient; the processor assesses from the computer-readable memory, computer-readable data representing a topological module of nodes, wherein the topological module represents the pre-emergent disease state; the processor maps the topological module to the first node data; the processor maps the topological module to the second node data; and the processor determines the pre-emergent disease state based on the mapping the topological module to the first node data and to the second node data. 